早产儿脑白质成熟模式:一项MRI T2弛豫各向异性和扩散张量成像研究
Cerebral White Matter Maturation Patterns in Preterm Infants: An MRI T2 Relaxation Anisotropy and Diffusion Tensor Imaging Study.
作者信息
Knight Michael J, Smith-Collins Adam, Newell Sarah, Denbow Mark, Kauppinen Risto A
机构信息
School of Experimental Psychology, University of Bristol, UK.
Clinical Research and Imaging Centre, University of Bristol, UK.
出版信息
J Neuroimaging. 2018 Jan;28(1):86-94. doi: 10.1111/jon.12486. Epub 2017 Dec 5.
BACKGROUND AND PURPOSE
Preterm birth is associated with worse neurodevelopmental outcome, but brain maturation in preterm infants is poorly characterized with standard methods. We evaluated white matter (WM) of infant brains at term-equivalent age, as a function of gestational age at birth, using multimodal magnetic resonance imaging (MRI).
METHODS
Infants born very preterm (<32 weeks gestation) and late preterm (33-36 weeks gestation) were scanned at 3 T at term-equivalent age using diffusion tensor imaging (DTI) and T2 relaxometry. MRI data were analyzed using tract-based spatial statistics, and anisotropy of T2 relaxation was also determined. Principal component analysis and linear discriminant analysis were applied to seek the variables best distinguishing very preterm and late preterm groups.
RESULTS
Across widespread regions of WM, T2 is longer in very preterm infants than in late preterm ones. These effects are more prevalent in regions of WM that myelinate earlier and faster. Similar effects are obtained from DTI, showing that fractional anisotropy (FA) is lower and radial diffusivity higher in the very preterm group, with a bias toward earlier myelinating regions. Discriminant analysis shows high sensitivity and specificity of combined T2 relaxometry and DTI for the detection of a distinct WM development pathway in very preterm infants. T2 relaxation is anisotropic, depending on the angle between WM fiber and magnetic field, and this effect is modulated by FA.
CONCLUSIONS
Combined T2 relaxometry and DTI characterizes specific patterns of retarded WM maturation, at term equivalent age, in infants born very preterm relative to late preterm.
背景与目的
早产与较差的神经发育结局相关,但标准方法难以很好地描述早产儿的脑成熟情况。我们使用多模态磁共振成像(MRI)评估了足月等效年龄婴儿脑白质(WM),将其作为出生时胎龄的函数。
方法
对极早产儿(胎龄<32周)和晚期早产儿(胎龄33 - 36周)在足月等效年龄时进行3T磁共振扫描,采用扩散张量成像(DTI)和T2弛豫测量法。使用基于纤维束的空间统计学分析MRI数据,并确定T2弛豫的各向异性。应用主成分分析和线性判别分析来寻找最能区分极早产和晚期早产组的变量。
结果
在广泛的脑白质区域,极早产儿的T2比晚期早产儿更长。这些效应在髓鞘形成较早且较快的脑白质区域更为普遍。DTI也得到了类似的结果,显示极早产组的分数各向异性(FA)较低,径向扩散率较高,且偏向于髓鞘形成较早的区域。判别分析表明,联合T2弛豫测量法和DTI对检测极早产儿独特的脑白质发育途径具有高敏感性和特异性。T2弛豫是各向异性的,取决于脑白质纤维与磁场之间的夹角,并且这种效应受FA调节。
结论
联合T2弛豫测量法和DTI能够描述在足月等效年龄时,相对于晚期早产儿,极早产儿脑白质成熟延迟的特定模式。
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